Mini Family 72V Input

Actual size: 2.28 x 2.2 x 0.5in 57,9 x 55,9 x 12,7mm Mini Family 72V Input C US C NRTL US DC-DC Converter Module S Features & Benefits DC input range: 43 110V (continuous) Isolated output Encapsulated circuitry for shock and vibration resistance Extended temperature range ( 55 to +100 C) Input surge withstand: 150V for 100ms DC output: 3.3 48V Programmable output: 10 to 110% Regulation: ±0.2% no load to full load Efficiency: Up to 88% Maximum operating temp: 100 C, full load Power density: up to 100W per cubic inch Height above board: 0.43in. (10,9mm) Parallelable, with N+M fault tolerance Low noise ZCS/ZVS architecture RoHS Compliant (with F or G pin option) Product Overview These DC-DC converter modules use advanced power processing, control and packaging technologies to provide the performance, flexibility, reliability and cost effectiveness of a mature power component. High frequency ZCS/ZVS switching provides high power density with low noise and high efficiency. Applications Railway/Transportation system applications including communications systems, information display, lighting, control systems, ticket machines, passenger entertainment, public address systems, door control, industrial power systems and power generation systems. For details on proper operation please refer to the: Design Guide & Applications Manual for Maxi, Mini, Micro Family. Absolute Maximum Ratings Parameter Rating Unit Notes to voltage -0.5 to +155 V DC to voltage -0.5 to +7.0 V DC to voltage -0.5 to +7.0 V DC to -OUT voltage -0.5 to +1.5 V DC -Sense to -OUT voltage 1.0 V DC Isolation voltage IN to OUT 3000 V RMS Test voltage IN to base 1500 V RMS Test voltage OUT to base 500 V RMS Test voltage Operating Temperature -55 to +100 C M-Grade Storage Temperature -65 to +125 C M-Grade Pin soldering temperature 500 (260) F ( C) <5 sec; wave solder 750 (390) F ( C) <7 sec; hand solder Mounting torque 5 (0.57) in-lbs (N-m) 6 each Part Numbering e.g. V72B24C250BL V72B B Output Voltage 3V3 = 3.3V 5 = 5V 8 = 8V 12 = 12V 15 = 15V 24 = 24V 28 = 28V 36 = 36V 48 = 48V Product Grade Temperatures ( C) Grade Operating Storage E = - 10 to +100-20 to +125 C = - 20 to +100-40 to +125 T = - 40 to +100-40 to +125 H = - 40 to +100-55 to +125 M = - 55 to +100-65 to +125 Output Power V OUT P OUT 3.3V 100W 5V 150W 8V 150W 12V 250W 15V 250W 24V 250W 28V 250W 36V 250W 48V 250W Pin Style Finish Blank: Short Tin/Lead L: Long Tin/Lead S: Short ModuMate Gold N: Long ModuMate Gold F: Short RoHS Gold G: Long RoHS Gold K: Extra Long RoHS Gold Baseplate Blank: Slotted 2: Threaded 3: Through-hole Page 1 of 11 06/2017 800 927.9474

Module Family Electrical Characteristics Electrical characteristics apply over the full operating range of input voltage, output load (resistive) and baseplate temperature, unless otherwise specified. All temperatures refer to the operating temperature at the center of the baseplate. MODULE INPUT SPECIFICATIONS Operating input voltage 43 72 110 V DC Per EN50155 and GBT-25119 Input surge withstand 150 V DC <100ms Undervoltage turn-on 41.7 42.6 V DC Undervoltage turn-off 35.2 36.5 V DC Overvoltage turn-off/on 111 115.5 121 V DC Disabled input current 1.5 ma pin low MODULE OUTPUT SPECIFICATIONS Output voltage setpoint ±1 % Of nominal output voltage. Nominal input; full load; 25 C Line regulation ±0.02 ±0.20 % Low line to high line; full load Temperature regulation ±0.002 ±0.005 % / C Over operating temperature range Power sharing accuracy ±2 ±5 % 10 to 100% of full load Of nominal output voltage. For trimming below 90% Programming range 10 110 % of nominal, a minimum load of 10% of maximum rated power may be required. to, ense to Absolute Maximum Ratings 3.3V 0.5 to 4.7 V DC Externally applied 5V 0.5 to 7.0 V DC Externally applied 8V 0.5 to 10.9 V DC Externally applied 12V 0.5 to 16.1 V DC Externally applied 15V 0.5 to 20.0 V DC Externally applied 24V 0.5 to 31.7 V DC Externally applied 28V 0.5 to 36.9 V DC Externally applied 36V 0.5 to 47.1 V DC Externally applied 48V 0.5 to 62.9 V DC Externally applied Note: The permissible load current must never be exceeded during normal, abnormal or test conditions. For additional output related application information, please refer to output connections on page 6. THERMAL RESISTANCE AND CAPACITY Parameter Min Typ Max Unit Baseplate to sink; flat, greased surface 0.16 C/Watt Baseplate to sink; thermal pad (P/N 20264) 0.14 C/Watt Baseplate to ambient 8.0 C/Watt Baseplate to ambient; 1000LFM 1.9 C/Watt Thermal capacity 83 Watt-sec/ C Page 2 of 11 06/2017 800 927.9474

Module Family Electrical Characteristics (Cont.) MODULE CONTROL SPECIFICATIONS Primary Side ( = Primary Control; = Parallel) bias voltage 5.50 5.75 6.00 V DC current = 1.0mA current limit 1.5 2.1 3.0 ma voltage = 5.5V During normal operation module disable 2.3 2.6 2.9 V DC Switch must be able to sink 4mA. See Fig. 2 module enable delay 4 7 ms module alarm 0.5 Vavg UV, OV, OT, module fault. See Figs. 3 and 5 resistance 0.9 1.0 1.1 MΩ See Fig. 3, converter off or fault mode emitter amplitude 5.7 5.9 6.1 Volts load >30Ω, <30pF emitter current 150 ma receiver impedance 375 500 625 Ω 25 C receiver threshold 2.4 2.5 2.6 Volts Minimum pulse width: 20ns drive capability 12 modules Without buffer amplifier Secondary Side ( = Secondary Control) bandgap voltage 1.21 1.23 1.25 V DC Referenced to ense resistance 990 1000 1010 Ω capacitance 0.033 µf module alarm 0 V DC With open trim; referenced to ense. See Fig. 7 MODULE GENERAL SPECIFICATIONS Remote sense (total drop) 0.5 V DC 0.25V per leg (sense leads must be connected to respective, output terminals) Isolation test voltage (IN to OUT)* 3000 V RMS Complies with reinforced insulation requirements Isolation test voltage (IN to base)* 1500 V RMS Complies with basic insulation requirements Isolation test voltage (OUT to base)* 500 V RMS Complies with operational insulation requirements Isolation resistance 10 MΩ IN to OUT, IN to baseplate, out to baseplate Weight (E, C, T grade) Weight (H, M grade) 3.1 3.5 3.9 ounces (89.3) (100.3) (111.3) (grams) 3.5 3.9 4.3 ounces (99.6) (110.6) (121.6) (grams) Temperature limiting 100 115 C See Figs. 3 and 5. Do not operate coverter >100 C. Agency approvals curus, ctüvus, CE UL60950-1, EN60950-1, CSA60950-1, IEC60950-1. With appropriate fuse in series with the +Input * Isolation test voltage, 1 minute or less. Note: Specifications are subject to change without notice. Page 3 of 11 06/2017 800 927.9474

MODULE SPECIFIC OPERATING SPECIFICATIONS 3.3V OUT, 100W (e.g. V72B3V3C100BL) Efficiency 80.0 82.2 % Nominal input; full load; 25 C Ripple and noise 185 232 mv p-p; Nominal input; full load; 20MHz bandwidth Output OVP setpoint 4.14 4.3 4.46 Volts 25 C; recycle input voltage or to restart (>100ms off) Dissipation, standby 4.4 5.4 Watts No load Output Current 0 30.3 Amps Current limit 30.9 34.8 41 Amps Output voltage 95% of nominal Short circuit current 21.2 34.8 41 Amps Output voltage <250mV 5V OUT, 150W (e.g. V72B5C150BL) Efficiency 84.0 85.0 % Nominal input; full load; 25 C Ripple and noise 120 150 mv p-p; Nominal input; full load; 20MHz bandwidth Output OVP setpoint 6.03 6.25 6.47 Volts 25 C; recycle input voltage or to restart (>100ms off) Dissipation, standby 7.9 8.6 Watts No load Output Current 0 30 Amps Current limit 30.6 34.5 40.5 Amps Output voltage 95% of nominal Short circuit current 21 34.5 40.5 Amps Output voltage <250mV 8V OUT, 150W (e.g. V72B8C150BL) Efficiency 84.5 85.4 % Nominal input; full load; 25 C Ripple and noise 220 275 mv p-p; Nominal input; full load; 20MHz bandwidth Output OVP setpoint 9.36 9.7 10.1 Volts 25 C; recycle input voltage or to restart (>100ms off) Dissipation, standby 5.9 6.9 Watts No load Output Current 0 18.75 Amps Current limit 19.1 21.6 25.4 Amps Output voltage 95% of nominal Short circuit current 5 21.6 25.4 Amps Output voltage <250mV 12V OUT, 250W (e.g. V72B12C250BL) Efficiency 86.5 87.6 % Nominal input; full load; 25 C Ripple and noise 300 375 mv p-p; Nominal input; full load; 20MHz bandwidth Output OVP setpoint 13.7 14.3 14.9 Volts 25 C; recycle input voltage or to restart (>100ms off) Dissipation, standby 8.5 9.5 Watts No load Output Current 0 20.83 Amps Current limit 21.2 23.9 28.2 Amps Output voltage 95% of nominal Short circuit current 14.5 23.9 28.1 Amps Output voltage <250mV 15V OUT, 250W (e.g. V72B15C250BL) Efficiency 85.1 86.3 % Nominal input; full load; 25 C Ripple and noise 400 500 mv p-p; Nominal input; full load; 20MHz bandwidth Output OVP setpoint 17.1 17.8 18.5 Volts 25 C; recycle input voltage or to restart (>100ms off) Dissipation, standby 8.3 8.8 Watts No load Output Current 0 16.67 Amps Current limit 17 19.2 22.6 Amps Output voltage 95% of nominal Short circuit current 11.6 19.2 22.6 Amps Output voltage <250mV Page 4 of 11 06/2017 800 927.9474

MODULE SPECIFIC OPERATING SPECIFICATIONS (CONT.) 24V OUT, 250W (e.g. V72B24C250BL) Efficiency 85.5 86.8 % Nominal input; full load; 25 C Ripple and noise 216 270 mv p-p; Nominal input; full load; 20MHz bandwidth Output OVP setpoint 27.1 28.1 29.1 Volts 25 C; recycle input voltage or to restart (>100ms off) Dissipation, standby 7.8 8.9 Watts No load Output Current 0 10.42 Amps Current limit 10.6 12 14.1 Amps Output voltage 95% of nominal Short circuit current 7.28 12 14.1 Amps Output voltage <250mV 28V OUT, 250W (e.g. V72B28C250BL) Efficiency 87.5 88.5 % Nominal input; full load; 25 C Ripple and noise 270 338 mv p-p; Nominal input; full load; 20MHz bandwidth Output OVP setpoint 31.5 32.7 33.9 Volts 25 C; recycle input voltage or to restart (>100ms off) Dissipation, standby 7.7 8.2 Watts No load Output Current 0 8.93 Amps Current limit 9.1 10.3 12.1 Amps Output voltage 95% of nominal Short circuit current 6.25 10.3 12.1 Amps Output voltage <250mV 36V OUT, 250W (e.g. V72B36C250BL) Efficiency 86.5 87.7 % Nominal input; full load; 25 C Ripple and noise 200 250 mv p-p; Nominal input; full load; 20MHz bandwidth Output OVP setpoint 40.4 41.9 43.4 Volts 25 C; recycle input voltage or to restart (>100ms off) Dissipation, standby 10.1 11 Watts No load Output Current 0 6.94 Amps Current limit 7.07 7.98 9.37 Amps Output voltage 95% of nominal Short circuit current 4.85 7.98 9.37 Amps Output voltage <250mV 48V OUT, 250W (e.g. V72B48C250BL) Efficiency 85.5 87.0 % Nominal input; full load; 25 C Ripple and noise 202 253 mv p-p; Nominal input; full load; 20MHz bandwidth Output OVP setpoint 53.7 55.7 57.7 Volts 25 C; recycle input voltage or to restart (>100ms off) Dissipation, standby 8.7 10.5 Watts No load Output Current 0 5.21 Amps Current limit 5.31 5.99 7.04 Amps Output voltage 95% of nominal Short circuit current 3.64 5.99 7.04 Amps Output voltage <250mV Page 5 of 11 06/2017 800 927.9474

Basic Module Operation C2* C4* F1* C1* 0.2µF C3* C5* For C1 C5, keep leads and connections short. Figure 1 Basic module operation requires fusing, grounding, bypassing capacitors.* See Maxi, Mini, Micro Design Guide. Output Connections and Considerations The permissible load current must never be exceeded during normal, abnormal or test conditions. Converters subject to dynamic loading exceeding 25% of rated current must be reviewed by Vicor Applications Engineering to ensure that the converter will operate properly. Under dynamic load, light load, or no load conditions, the converter may emit audible noise. Converters that utilize remote sense may require compensation circuitry to offset the phase lag caused by the external output leads and load impedance. Remote Sense leads must be protected for conditions such as lead reversal, noise pickup, open circuit, or excessive output lead resistance between the sense point and the converters output terminals. For applications that may draw more than the rated current, a fast acting electronic circuit breaker must be utilized to protect the converter. Under no circumstance should the rated current be exceeded. Utilizing or testing of current limit or short circuit current will damage the converter. Ensure that the total output capacitance connected to the converter does not exceed the limits on Page 16, Maximum Output Capacitance, of the design guide. Comprehensive Online Application Information The Design Guide and Applications Manual includes: Application circuits Design requirements EMC considerations Current sharing in power arrays Thermal performance information Recommended soldering methods Accessory modules filtering, rectification, front-ends Mounting options...and more. CLICK HERE TO VIEW DESIGN GUIDE Also at vicorpower.com PowerBench online configurators Over 20 Application Notes Online calculators thermal, trimming, hold-up PDF data sheets for ALL Vicor products Page 6 of 11 06/2017 800 927.9474

Primary Control - PIN Module Enable/Disable The module may be disabled by pulling to 0V (2.3V max) with respect to the Input. This may be done with an open collector transistor, relay, or optocoupler. Converters may be disabled with a single transistor or relay either directly or via OR ing diodes for 2 or more converters. See Figure 2. Primary Auxiliary Supply During normal operation only, the Pin can source 5.7V @ 1.5mA. In the example shown in Figure 4, powers a module enabled LED. Module Alarm The module contains watchdog circuitry which monitors input voltage, operating temperature and internal operating parameters. In the event that any of these parameters are outside of their allowable operating range, the module will shut down and will go low. will periodically go high and the module will check to see if the fault (as an example, Input Undervoltage) has cleared. If the fault has not been cleared, will go low again and the cycle will restart. The pin will go low in the event of a fault and return to its normal state after the fault has been cleared. See Figures 3 and 5. Disable Disable = <2.3V 1M SW1 Auto Restart 2-20 ms typ. f (VIN) SW1, 2, & 3 shown in "Fault" position 5.7V DC (0-3mA) 1 Not applicable for 300VDC input family Input Undervoltage Input Overvoltage (See Note 1) Overtemperature Module Faults SW2 50Ω SW3 1.23 V DC 1k 6k OUT Figure 2 Module enable/disable Figure 3 / module alarm logic "Module Enabled" 4kΩ Fault 5.7V 1.23V 40µs typ. 2 20ms typ. Figure 4 LED on-state indicator Figure 5 / module alarm timing Optocoupler 4kΩ 1.00V Alarm Figure 6 Isolated on-state indicator Figure 7 Secondary side on-state indicator Page 7 of 11 06/2017 800 927.9474

Secondary Control - PIN Output Voltage Programming The output voltage of the converter can be adjusted or programmed via fixed resistors, potentiometers or voltage DACs. See Figure 8. Figure 8 Output voltage trim down and trim up circuit Trim Down 1. This converter is not a constant power device it has a constant current limit. Hence, available output power is reduced by the same percentage that output voltage is trimmed down. Do not exceed maximum rated output current. 2. The trim down resistor must be connected between the and -S pins. Do not bypass the pin directly with a capacitor. Trim Up Error Amplifier 1. The converter is rated for a maximum delivered power. To ensure that maximum rated power is not exceeded, reduce maximum output current by the same percentage increase in output voltage. 2. The trim up resistor must be connected between the and pins. Do not bypass the pin directly with a capacitor. 3. Do not trim the converter above maximum trim range (typically +10%) or the output over voltage protection circuitry may be activated. Parallel Bus - PIN Parallel Operation + + 100Ω typ. R d (Ω) = 1kΩ 1.23V 1,000 V OUT V NOM V OUT The pin supports paralleling for increased power with N+1 (N+M) redundancy. Modules of the same input voltage, output voltage, and power level will current share if all pins are suitably interfaced. 0.033µF -S Ru Trim Up Rd Trim Down 1,000 ( V OUT 1.23) V NOM R U (Ω) = 1,000 1.23 (V OUT V NOM ) Trim resistor values calculated automatically: On-line calculators for trim resistor values are available on the vicor website at: asp.vicorpower.com/calculators/calculators.asp?calc=1 Resistor values can be calculated for fixed trim up, fixed trim down and for variable trim up or down. Load Compatible interface architectures include the following: AC coupled single-wire interface. All pins are connected to a single communication bus through 0.001µF (500V) capacitors. This interface supports current sharing and is fault tolerant except for the communication bus. Up to three converters may be paralleled by this method. See Figure 9. Transformer coupled interface. For paralleling four or more converters a transformer coupled interface is required, and under certain conditions a buffer circuit. For details on parallel operation please refer to the Design Guide & Applications Manual for Maxi, Mini, Micro Family. + Parallel Bus 0.2µF 0.001µF R1* Low inductance ground plane or bus 0.2µF 0.001µF R1* Figure 9 AC coupled single-wire interface * See Maxi, Mini, Micro Design Guide + Parallel Bus Number of Converters in Parallel 2 75 3 50 4 33 T1 T2 0.2µF R1* 0.2µF R1* Figure 10 Transformer-coupled interface *R1 value Ω Module 1 Module 2 Module 1 Module 2 5 or more refer to application note: Designing High-Power Arrays using Maxi, Mini, Micro Family DC-DC Converters Page 8 of 11 06/2017 800 927.9474

Parallel Bus Output Module 1 The and power buses should be designed to minimize and balance parasitic impedance from each module output to the load. The ense pins must be tied together to form a ense bus. This must be Kelvin connected to at a single point. The ense pins should be tied together to form a ense bus. This must be Kelvin connected to at a single point. Module 2 Load At the discretion of the power system designer, a subset of all modules within an array may be configured as slaves by connecting to. OR ing diodes may be inserted in series with the pins of each module to provide module output fault tolerance. Module N+1 The ense and -Sense leads should be routed in close proximity to each other on the printed circuit board. If wires are used to connect the converters on a B to an external load, the Sense leads should be twisted together to reduce noise pickup. Figure 11 N+1 module array output connections PIN STYLES* Designator Description Finish Notes (None) Short Tin/Lead Requires in-board, mounting L Long Tin/Lead On-board mounting for 0.065 boards S Short ModuMate Gold SurfMate or in-board socket mounting N Long ModuMate Gold On-board socket mounting F Short RoHS Gold Select for RoHS compliant in-board solder, socket, or SurfMate mounting G Long RoHS Gold Select for RoHS compliant on-board solder or socket mounting K Extra Long RoHS Gold Select for RoHS compliance on-board mounting for thicker Bs (not intended for socket or Surfmate mounting) * Pin style designator follows the B after the output power and precedes the baseplate designator. Ex. V72B12T250BN2 Long ModuMate Pins Storage Vicor products, when not installed in customer units, should be stored in ESD safe packaging in accordance with ANSI/ESD S20.20, Protection of Electrical and Electronic Parts, Assemblies and Equipment and should be maintained in a temperature controlled factory/ warehouse environment not exposed to outside elements controlled between the temperature ranges of 15 C and 38 C. Humidity shall not be condensing, no minimum humidity when stored in an ESD compliant package. Page 9 of 11 06/2017 800 927.9474

2 3.700* 7,78 1.000 * 25,40 1.400 * 35,56 ns Mechanical Drawings 4 8 7 6 5 (9X) PLATED THROUGH HOLE DIA Converter Pins No. Function Label 1 + 2 Primary Control 3 Parallel 4 5 6 ense 7 Secondary Control 8 ense 9 + * DENOTES TOL= ± 0.003 ±0,08 Figure 12 Module outline FULL R (6X) Slotted (6X) 0.13 3,3 Threaded 4-40 UNC-2B (6X) Thru Hole #30 Drill Thru (6X) (0.1285) 0.23 5,8 (REF) 0.300 ±0.015 7,62 ±0,38 0.300 ±0.015 7,62 ±0,38 0.400 10,16 1 (ALL MARKINGS THIS SURFACE) 2 9 8 2.20 55,9 1.76 44,7 3 0.700 17,78 1.000 25,40 1.400 35,56 4 7 6 5 0.50 ±0.02 12,7 ±0,5 style 2 & 3 baseplates only (4X)*** 1.900 48,26 Pin C L 0.150 DIA,(2X) 3,81 0.080 DIA,(7X) 2,03 * Style 1 baseplate only ** Style 2 & 3 baseplates *** Reserved for Vicor accessories Not for mounting C L Pin center line 0.12* 0.20** 3,1 5,1 DIMENSION L PIN SHORT.55±.015 [14.0±.38] NOTES: PIN LONG.63±.015 [16.0±.38] 1. MATERIAL: PIN EXTRA LONG -.71±.015 [18.0±.38] BASE: 6000 SERIES ALUMINUM COVER: LCP, ALUMINUM 3003 H14 PINS: RoHS PINS GOLD PLATE 30 MICRO INCH MIN; NON-RoHS 72V Input 2.20 55,9 (REF.) PINS: TIN/LEAD 90/10 BRIGHT NOTES: 1. MATERIAL: 2. DIMENSIONS AND VALUES IN BRACKETS ARE METRIC 3. MANUFACTURING CONTROL IS IN PLACE TO ENSURE THAT THE SPACING BASE: 6000 SERIES ALUMINUM BETWEEN THE MODULES LABEL SURFACE TO THE INTED CIRCUIT BOARD COVER: LCP, ALUMINUM 3003 H14 OF THE APPLICATION RANGES FROM DIRECT CONTACT (ZERO), TO THE PINS: RoHS PINS GOLD PLATE 30 MICRO INCH MIN; NON-RoHS MAXIMUM GAP AS CALCULATED FROM THE TOLERANCE STACK-UP PINS: TIN/LEAD 90/10 BRIGHT 2. DIMENSIONS AND VALUES IN BRACKETS ARE METRIC AND IS NOT SUBJECT NEGATIVE TOLERANCE ACCUMULATION 3. MANUFACTURING CONTROL IS IN PLACE TO ENSURE THAT THE SPACING BETWEEN THE MODULES LABEL SURFACE TO THE INTED CIRCUIT BOARD OF THE APPLICATION RANGES FROM DIRECT CONTACT (ZERO), TO THE MAXIMUM GAP AS CALCULATED FROM THE TOLERANCE STACK-UP AND IS NOT SUBJECT NEGATIVE TOLERANCE ACCUMULATION 0.01 0.35 (2X) 8,8 ALUMINUM BASEPLATE 0.43 10,9 0.54 (9X) 13,7 2.28 57,9 R 0.49 12,4 0.06 1,5 1.30 33,0 0.65 16,5 (3X) Pin Style 1&S (Short Pin) 0.62 (9X) Pin Style 2&N 15,7 (Long Pin) 0.71 Pin Style K 18,0 (9X) (Extra Long Pin) 2.000 50,80 0.10 2,5 0.10 X 45 2,5 CHAMFER FULL R (6X) 0.130 (6X) 3,30 Use a 4-40 Screw (6X) Torque to: 5 in-lbs 0.57 N-m INBOARD SOLDER MOUNT ONBOARD SOLDER MOUNT ALL MARKINGS THIS SURFACE 0.062 ±0.010 B THICKNESS 1,57 ±0,25 PLATED THROUGH HOLE 1.790** DIA 0.06 45,47 R (4X) 0.158 1,5 4,01 (7X) (2X) SHORT PIN STYLE 0.094 ±0.003 2,39 ±0,08 0.164 ±0.003 4,16 ±0,08 LONG PIN STYLE 0.094 ±0.003 2,39 ±0,08 0.164 ±0.003 4,16 ±0,08 ALUMINUM BASEPLATE 1.900* 48.26 48,26 1 2 3 4 1.575** 40,00 PINS STYLES SOLDER:TIN / LEAD PLATED MODUMATE: GOLD PLATED COPPER RoHS: GOLD PLATED COPPER 9 8 7 6 5 For Soldering Methods and Procedures Please refer to: THE MAXI, MINI, MICRO Design Guide. 0.400* 10,16 0.700* 17,78 043 0.45 11,5 0.53 13,5 Unless otherwise specified, dimensions are in inches mm Decimals Tol. Angles 0.195 4,95 1.000* 25,40 1.400* 35,56 ±0.003 * DENOTES TOL = ±0,08 ** B WINDOW 0.XX ±0.01 ±0.25 ±1 0.XXX ±0.005 ±0.127 Figure 13 B mounting specifications Page 10 of 11 06/2017 800 927.9474

Vicor s comprehensive line of power solutions includes high density AC-DC and DC-DC modules and accessory components, fully configurable AC-DC and DC-DC power supplies, and complete custom power systems. Information furnished by Vicor is believed to be accurate and reliable. However, no responsibility is assumed by Vicor for its use. Vicor makes no representations or warranties with respect to the accuracy or completeness of the contents of this publication. Vicor reserves the right to make changes to any products, specifications, and product descriptions at any time without notice. Information published by Vicor has been checked and is believed to be accurate at the time it was printed; however, Vicor assumes no responsibility for inaccuracies. Testing and other quality controls are used to the extent Vicor deems necessary to support Vicor s product warranty. Except where mandated by government requirements, testing of all parameters of each product is not necessarily performed. Specifications are subject to change without notice. Visit http://www.vicorpower.com/dc-dc-converters-board-mount/high-density-dc-dc-converters for the latest product information. Vicor s Standard Terms and Conditions and Product Warranty All sales are subject to Vicor s Standard Terms and Conditions of Sale, and Product Warranty which are available on Vicor s webpage (http://www.vicorpower.com/termsconditionswarranty) or upon request. Life Support Policy VICOR S ODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXESS IOR WRITTEN APOVAL OF THE CHIEF EXECUTIVE OFFICER AND GENERAL COUNSEL OF VICOR CORPORATION. As used herein, life support devices or systems are devices which (a) are intended for surgical implant into the body, or (b) support or sustain life and whose failure to perform when properly used in accordance with instructions for use provided in the labeling can be reasonably expected to result in a significant injury to the user. A critical component is any component in a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system or to affect its safety or effectiveness. Per Vicor Terms and Conditions of Sale, the user of Vicor products and components in life support applications assumes all risks of such use and indemnifies Vicor against all liability and damages. Intellectual Property Notice Vicor and its subsidiaries own Intellectual Property (including issued U.S. and Foreign Patents and pending patent applications) relating to the products described in this data sheet. No license, whether express, implied, or arising by estoppel or otherwise, to any intellectual property rights is granted by this document. Interested parties should contact Vicor s Intellectual Property Department. Vicor Corporation 25 Frontage Road Andover, MA, USA 01810 Tel: 800-735-6200 Fax: 978-475-6715 email Customer Service: custserv@vicorpower.com Technical Support: apps@vicorpower.com Page 11 of 11 06/2017 800 927.9474